Fluvial sediments accumulated in the bottoms of river valleys downstream from large cities are characterised by higher levels of heavy metal content, which poses a threat to the environment and humans. This study presents a comprehensive assessment of the degree of pollution of four alluvial sediment profiles (80 samples), collected from the bottom of the Bystrzyca river valley downstream from Lublin, conducted with the use of five geochemical indices. Channel deposits and sediments (alluvial soils) sampled from the floodplain were analysed. The content levels of the six heavy metals under study were as follows: Cd: 10.6–291.2 mg/kg, Cr: 53.1–292.4 mg/kg, Cu: 20.4–223.1 mg/kg, Ni: 2.9–19.3, Pb: 39.3–280.3, Zn: 108.9–991.4 mg/kg. The horizontal and vertical variation of the pollution level was linked with the history of anthropogenic pressure on the one hand, and the geomorphological location of a given profile on the other. Heavy metal content in the samples did not show any correlation with grain size composition, organic matter content, and Fe and Mn content. Cadmium was the element whose concentration levels were comparable with those in alluvial sediments of rivers in industrialised areas while the indices for the other metals showed varied levels of pollution: from low to high. However, the ecological risk is high for all samples as indicated by the synthetic potential ecological risk index, which takes into account the toxicity of all the metals under study.

alluvia, alluvial soils, Bystrzyca river, heavy metals

Bojakowska, I., 1994. Impact of human factor on geochemical processes in surficial layers of lithosphere. Instructions and methods of geological studies 53 (in Polish). Państwowy Instytut Geologiczny, Warszawa.

Bojakowska, I., Sokołowska, G., 1996. Heavy metals in the Bystrzyca river flood plain. Geological Quarterly 40(3): 467–480.

Bojakowska, I., Sokołowska, G., 1998. Geochemical classes of water sediments quality. Przegląd Geologiczny 46: 49–54.

Ciszewski, D., 1997. Source of pollution as a factor controlling distribution of heavy metals in bottom sediments of Chechło River (south Poland). Environmental Geology 29(1/2): 50–57. DOI:10.1007/s002540050103

Ciszewski, D., 1998. Impact of river channel morphology on the accumulation of heavy metals in bottom deposits (in Polish) 46: 246–270.

Ciszewski, D., 2001. Possibilities and problems of applications of heavy metals in dating of alluvial sediments on the example of middle Odra river (in Polish). Czasopismo Geograficzne 72: 53–69.

Ciszewski, D., 2002. Record of industrial activity in fluvial sediments. In: Record of Human Activity in Natural Environment I (in Polish), P. Szwarczewski, E. Smolska (eds.), WGiSR, WSA w Łomży, Warszawa–Łomża: 23–28.

Ergin, M., Saydam, C., Basturk, O., Erdem, E., Yoruk, R., 1991. Metal concentrations in surface sediments from the two coastal inlets (Golden Horn Estuary and Izmit Bay) of the northeastern Sea of Marmara. Chemical Geology 91: 269–285. DOI: 10.1016/0009-2541(91)90004-B

Håkanson, L., 1980. An Ecological Risk Index for Aquatic Pollution Control: A Sedimentological Approach. Water Res., 14: 975–1001.

Lis, S., Pasieczna, A., 1995. Geochemical Atlas of Poland 1:2 500 000 (in Polish). Państwowy Instytut Geologiczny. Warszawa

Michalczyk, Z., Bartoszewski, S., Turczyński, M., Głowacki, S., Zielińska, B., 1997. Natural and human conditions of river discharge (in Polish). In: Strategy of Use and Protection of Water in the Bystrzyca River Basin (in Polish), Z. Michalczyk (ed.), Wydawnictwo UMCS, Lublin: 32–43.

Martin, C.W., 2000. Heavy metal trends in floodplain sediments and valley fill, River Lahn, Germany. CATENA 39: 53–68. DOI: 10.1016/S0341-8162(99)00080-6

Müller, G., 1979. Schwermetalle in den Sedimenten des Rheins – Veränderungen seit 1971. Umschau 24: 778–783.

Plak, A., Melke, J., Dębicki, R., 2006. Heavy metals (Ni, Cu, Pb) in soils of Bystrzyca valley. Ecological Chemistry and Engineering 13(9): 959–964.

Rubin, H., Rubin, K., Siodłak, A., Skuza, P., 2011. Assessment of contamination of the bottom sediments of the Stoła river with selected metals and metalloids within the urban-industrial area of Tarnowskie Góry (in Polish). Biuletyn Państwowego Instytutu Geologicznego 445: 615–623.

Shi, X., Wang, J., 2013. Comparison of different methods for assessing heavy metal contamination in street dust of Xianyang City, NW China. Environmental Earth Sciences 68(8): 2409–2415.

Sokołowska, G., Szwarczewski, P., 1998. Heavy metals in different ages alluvia of Bzura river. Przegląd Geologiczny 46: 417–420.

Soliman, N.F., Nasr, S.M., Okbah M.A., 2015. Potential ecological risk of heavy metals in sediments from the Mediterranean coast, Egypt. Journal of Environmental Health Science and Engineering, 13, 70. DOI: 10.1186/s40201-015-0223-x

Szwarczewski, P., 1998. Heavy metals in different ages alluvia of Vistula river in the vicinity of Toruń (in Polish). Przegląd Geologiczny 46: 1286–1288.

Szwarczewski, P., 2002. Changes of heavy metals content in alluvia of lower Vistula river during the last 100 years (in Polish). In: Record of Human Activity in Natural Environment I (in Polish), P. Szwarczewski, E. Smolska (eds.), WGiSR, WSA w Łomży, Warszawa–Łomża: 121–129.

Thonon, I., 2006. Deposition of sediment and associated heavy metals on floodplains. Netherlands Geographical Studies 337: 1–173.

Zgłobicki, W., 2008. Geochemical record of human activity in slope and alluvial sediments (in Polish). Wydawnictwo UMCS, Lublin.

Zgłobicki, W., Telecka, M., Pasierbińska, A., 2015. Impact of physicochemical characteristics of colluvial and alluvial soils on Cd, Cu, Pb and Zn content (East Poland). Polish Journal of Soil Sciences 48(2): 213–228. DOI: 10.17951/pjss/2015.48.2.213